Extracellular Sodium Dependence of the Conduction Velocity-Calcium Relationship: Evidence of Ephaptic Self-Attenuation

Our laboratory previously demonstrated that perfusate sodium and potassium concentrations can modulate cardiac conduction velocity (CV) consistent with theoretical predictions of ephaptic coupling (EpC). EpC depends on the ionic currents and intercellular separation in sodium channel rich intercalated disk microdomains like the perinexus. We suggested that perinexal width (WP) correlates with changes in extracellular calcium ([Ca2+]o). Here, we test the hypothesis that increasing [Ca2+]o reduces WP and increases CV. Mathematical models of EpC also predict that reducing WP can reduce sodium driving force and CV by self-attenuation. Therefore, we further hypothesized that reducing WP and extracellular sodium ([Na+]o) will reduce CV consistent with ephaptic self-attenuation. Transmission electron microscopy revealed that increasing [Ca2+]o (1 to 3.4 mM) significantly decreased WP. Optically mapping wild-type (WT) (100% Cx43) mouse hearts demonstrated that increasing [Ca2+]o increases transverse CV during normonatremia (147.3 mM), but slows transverse CV during hyponatremia (120 mM). Additionally, CV in heterozygous (∼50% Cx43) hearts was more sensitive to changes in [Ca2+]o relative to WT during normonatremia. During hyponatremia, CV slowed in both WT and heterozygous hearts to the same extent. Importantly, neither [Ca2+]o nor [Na+]o altered Cx43 expression or phosphorylation determined by Western blotting, or gap junctional resistance determined by electrical impedance spectroscopy. Narrowing WP, by increasing [Ca2+]o, increases CV consistent with enhanced EpC between myocytes. Interestingly, during hyponatremia, reducing WP slowed CV, consistent with theoretical predictions of ephaptic self-attenuation. This study suggests that serum ion concentrations may be an important determinant of cardiac disease expression.

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Extracellular Sodium Dependence of GnRH‐Stimulated Growth Hormone Release in Goldfish Pituitary Cells

Journal of Neuroendocrinology ◽

10.1046/j.1365-2826.1997.00572.x ◽

1997 ◽

Vol 9 (3) ◽

pp. 207-216 ◽

Cited By ~ 20

Author(s):

Fredrick Van Goor ◽

Jeffrey I. Goldberg ◽

John P. Chang

Keyword(s):

Growth Hormone ◽

Pituitary Cells ◽

Hormone Release ◽

Growth Hormone Release ◽

Sodium Dependence ◽

Extracellular Sodium

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Abstract 16378: Increased Extracellular Sodium and Calcium Modify the Extracellular Potassium and Cardiac Conduction Velocity Relationship in a Langendorff-perfused Guinea Pig Heart

Circulation ◽

10.1161/circ.142.suppl_3.16378 ◽

2020 ◽

Vol 142 (Suppl_3) ◽

Author(s):

David Ryan King ◽

Michael ENTZ ◽

Grace Blair ◽

Ian Crandell ◽

Alexandra Hanlon ◽

...

Keyword(s):

Guinea Pig ◽

Conduction Velocity ◽

Cardiac Conduction ◽

Extracellular Potassium ◽

Guinea Pig Heart ◽

Conduction Loss ◽

High K ◽

Velocity Relationship ◽

Severe Hyperkalemia ◽

Extracellular Sodium

Background: Previous studies have demonstrated a biphasic relationship between extracellular potassium (K o ) and cardiac conduction velocity (CV). With moderate hyperkalemia, CV increases in what is referred to as supernormal conduction, but further increases in K o lead to severe conduction slowing and asystole. We recently demonstrated that altering extracellular sodium (Na o ) and extracellular calcium (Ca o ) modulates CV dependence on gap junctions (GJs). We have also shown that increasing Na o and Ca o can attenuate conduction loss caused by global ischemia ischemia. The purpose of this study was to determine if increasing Na o and Ca o would alter the K o -CV relationship and preserve CV at high K o . Hypothesis: Increasing Na o and Ca o will mitigate conduction slowing and the incidence of asystole associated with severe hyperkalemia in conditions of both normal and uncoupled GJs. Methods: Langendorff-perfused guinea pig hearts were optically mapped to measure CV. Na o was set to 145 or155mM and Ca o to 1.25 or 2.0mM. K o was varied from 4.6, 6.4, 8, to 10 mM in each experiment. Perfusion order was blinded and randomized. GJs were inhibited using carbenoxolone. Results: A biphasic K o -CV relationship was observed under all conditions. Maximum CV was achieved at either 6.4 or 8.0mM K o followed by a decrease in CV with increased K o . Importantly, the degree of CV slowing in the presence of 10mM K o was significantly reduced with the 155mM Na o / 2.0mM Ca o perfusate compared to all other Na o /Ca o combinations. Carbenoxolone reduced CV across all K o , but did not alter the K o -CV relationship. With 145mM Na o / 1.25mM Ca o , all hearts became asystolic at K o =10.0mM. Increasing Na o and Ca o significantly reduced the incidence of asystole at K o =10.0mM. Conclusions: Elevating Na o and Ca o preserves CV during severe hyperkalemia with or without strong GJ coupling. Increasing Na o and Ca o significantly reduces the incidence of asystole during severe hyperkalemia. These data suggest that non-linear and combinatorial effects of sodium, calcium, and GJ uncoupling can differentially modulate cardiac conduction during hyperkalemic perfusion. These results have important implications for cardioplegic arrest and ischemic heart disease when potassium and calcium homeostasis are disrupted.

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How extracellular sodium replacement affects the conduction velocity distribution of rats’ peripheral nerves

Česká a slovenská neurologie a neurochirurgie ◽

10.14735/amcsnn2019209 ◽

2019 ◽

Vol 82/115 (2) ◽

pp. 209-214

Author(s):

Seckin Tuncer ◽

Murat Celen

Keyword(s):

Velocity Distribution ◽

Conduction Velocity ◽

Peripheral Nerves ◽

Conduction Velocity Distribution ◽

Extracellular Sodium ◽

Sodium Replacement

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The conduction velocity-potassium relationship in the heart is modulated by sodium and calcium

Pflügers Archiv - European Journal of Physiology ◽

10.1007/s00424-021-02537-y ◽

2021 ◽

Cited By ~ 1

Author(s):

D. Ryan King ◽

Michael Entz ◽

Grace A. Blair ◽

Ian Crandell ◽

Alexandra L. Hanlon ◽

...

Keyword(s):

Conduction Velocity ◽

Cardiac Conduction ◽

Extracellular Potassium ◽

Primary Role ◽

Junctional Coupling ◽

Severe Hyperkalemia ◽

Gap Junctional ◽

Extracellular Sodium ◽

Gap Junctional Coupling ◽

Ephaptic Coupling

Abstract The relationship between cardiac conduction velocity (CV) and extracellular potassium (K+) is biphasic, with modest hyperkalemia increasing CV and severe hyperkalemia slowing CV. Recent studies from our group suggest that elevating extracellular sodium (Na+) and calcium (Ca2+) can enhance CV by an extracellular pathway parallel to gap junctional coupling (GJC) called ephaptic coupling that can occur in the gap junction adjacent perinexus. However, it remains unknown whether these same interventions modulate CV as a function of K+. We hypothesize that Na+, Ca2+, and GJC can attenuate conduction slowing consequent to severe hyperkalemia. Elevating Ca2+ from 1.25 to 2.00 mM significantly narrowed perinexal width measured by transmission electron microscopy. Optically mapped, Langendorff-perfused guinea pig hearts perfused with increasing K+ revealed the expected biphasic CV-K+ relationship during perfusion with different Na+ and Ca2+ concentrations. Neither elevating Na+ nor Ca2+ alone consistently modulated the positive slope of CV-K+ or conduction slowing at 10-mM K+; however, combined Na+ and Ca2+ elevation significantly mitigated conduction slowing at 10-mM K+. Pharmacologic GJC inhibition with 30-μM carbenoxolone slowed CV without changing the shape of CV-K+ curves. A computational model of CV predicted that elevating Na+ and narrowing clefts between myocytes, as occur with perinexal narrowing, reduces the positive and negative slopes of the CV-K+ relationship but do not support a primary role of GJC or sodium channel conductance. These data demonstrate that combinatorial effects of Na+ and Ca2+ differentially modulate conduction during hyperkalemia, and enhancing determinants of ephaptic coupling may attenuate conduction changes in a variety of physiologic conditions.

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